KR20120076296A - Jig for ceramic filter joining - Google Patents

Abstract

PURPOSE: A joint jig for manufacturing a ceramic filter is provided to improve productivity with a simplified manufacturing process by pressurizing a plurality of ceramic honeycombs at the same time. CONSTITUTION: A joint jig for manufacturing a ceramic filter comprises a plurality of joint guides and a coupling unit. The ceramic filter(10) is inserted into the joint guides. The inner surface of the joint guides comprises the shape corresponding to the outer surface of the ceramic filter. The joint guides pressurize the ceramic filter. The coupling unit is installed on the outer surfaces of the joint guides. The coupling unit couples the joint guides each other.

Description

Jigs for ceramic filter joining

The present invention relates to a joining jig for producing a ceramic filter, and more particularly, to a joining jig for manufacturing a ceramic filter suitable for manufacturing a large ceramic filter.

Diesel engines have high thermal efficiency, but due to their combustion characteristics, nitrogen oxides (NO _X ) and particulate matter (Particulate Matters (PM)) are emitted more than gasoline engines. In particular, as the results of studies showing that particulate matter causes lung cancer are increasing in concern about human hazards.

As a result, regulations on automobile exhaust gas are expanding all over the world, and research and development to reduce particulate matter and nitrogen oxide are being actively conducted. In order to reduce particulate matter, diesel particulate filter (DPF) is known as the most effective technology, and to reduce nitrogen oxides, SCR catalyst, NO _X Post-treatment techniques such as Trap are being developed.

DPF is manufactured by joining ceramic honeycomb segments having porous bulkheads, and physically collecting particulate matter in exhaust gas of a diesel engine using a filter, and after a certain distance, the particulate matter is fired at or above the ignition temperature (550 ° C). It is a device to reduce pollutants by burning exhausted particulate matter by raising exhaust gas temperature.

On the other hand, large DPFs are inserted in the case of large trucks or large buses. When a large number of ceramic honeycomb segments are joined to manufacture large DPFs, the durability of the large DPFs is easily reduced even after slight impact or vibration because the durability is reduced after firing. .

In order to prevent this, generally, a plurality of ceramic honeycomb segments are joined to form a ceramic honeycomb structure, and then a plurality of ceramic honeycomb structures are joined to manufacture a DPF. In this case, an impact mitigating layer is formed between each ceramic honeycomb structure to prevent breakage of the DPF, and a spacer is used to maintain a constant gap between the ceramic honeycomb structures.

However, by inserting the spacer, there is a problem that the bonding efficiency of the bonding material is lowered, the durability and filtration efficiency of the DPF is reduced, the process is complicated, the productivity is reduced.

In addition, when joining a plurality of ceramic honeycomb structures, a bonding material is applied to the joint surface of the ceramic honeycomb structure, and then the surfaces of the ceramic honeycomb structure are pressed to each other. There is a problem that the displacement is reduced so that the straightness of the DPF.

An object of the present invention is to provide a joining jig for producing a ceramic filter suitable for producing large DPFs.

Furthermore, an object of this invention is to provide the joining jig for manufacturing a ceramic filter which can manufacture DPF which is excellent in filtration efficiency and durability.

Furthermore, an object of this invention is to provide the joining jig for manufacturing a ceramic filter with a simple manufacturing process of DPF.

Furthermore, an object of the present invention is to provide a bonding electrode for producing a ceramic filter which prevents the binder from flowing out of the DPF and improves the straightness of the DPF.

Bonding jig for manufacturing a ceramic filter according to an aspect of the present invention for achieving the above object is a ceramic filter is inserted therein, the inner surface has a shape corresponding to the outer surface of the ceramic filter, pressurizing the ceramic filter It is provided on a plurality of bonding guides and a portion of the outer surface of the bonding guide, and includes a coupling means for mutually bonding the bonding guides in contact with each other.

In addition, the coupling means may be one of a tension spring, a spring-type cicada ring or a compression spring.

In addition, at both ends of the guide may be formed stepped to correspond to the end of the other guide in contact with the guide.

In addition, the inner surface of the bonding guide may further include an elastic means for buffering the ceramic filter.

In addition, the elastic means may be one of a rubber band or a leaf spring.

According to the bonding jig for manufacturing a ceramic filter according to the present invention, the DPF is manufactured without the use of a spacer so that the filtration efficiency and durability are good.

In addition, since the DPF is manufactured by simultaneously pressing a plurality of ceramic honeycomb assemblies using a plurality of coupling members, the manufacturing process is simple and the productivity is improved.

In addition, by attaching a buffer pad to the inner surface of the coupling member, the bonding material is prevented from flowing out of the DPF and the straightness of the DPF is improved.

1 is a view showing the configuration of a bonding jig for manufacturing a ceramic filter using a tension spring according to an embodiment of the present invention,
2 is a view showing the configuration of a bonding jig for manufacturing a ceramic filter using a spring-type cicada ring,
3 is a view showing the configuration of a bonding jig for manufacturing a ceramic filter using a compression spring;
Figure 4 is a view showing the configuration of a bonding jig for manufacturing a ceramic filter with a rubber band attached to the inner surface of the coupling member,
5 is a view showing the configuration of a bonding jig for manufacturing a ceramic filter with a leaf spring attached to the inner surface of the coupling member.

Hereinafter, the configuration and operation of the bonding jig for manufacturing a ceramic filter of the present invention according to the accompanying drawings will be described in more detail.

1 is a view showing the configuration of a bonding jig for manufacturing a ceramic filter using a tension spring according to an embodiment of the present invention, Figure 2 is a view showing the configuration of a bonding jig for manufacturing a ceramic filter using a spring-type cicada ring, 3 is a diagram illustrating a configuration of a bonding jig for manufacturing a ceramic filter using a compression spring.

1 to 3, the bonding jig for manufacturing a ceramic filter according to an exemplary embodiment of the present invention has a shape in which a ceramic filter 10 is inserted therein and an inner surface thereof corresponds to an outer surface of the ceramic filter 10. It is provided with a plurality of bonding guides 100 for pressing the ceramic filter 10 and a portion of the outer surface of the bonding guide 100, and includes a coupling means for mutually bonding the bonding guides 100 in contact with each other .

The bonding jig for manufacturing a ceramic filter according to an embodiment may be a bonding jig that may be used for manufacturing the ceramic filter 10 such as a large DPF, for example, and may include a plurality of bonding guides 100 and coupling means. .

The joining guide 100 corresponds to a body of a joining jig for manufacturing a ceramic filter surrounding the ceramic filter 10 during the joining process, and two or more joining guides 100 are used in combination with each other. In the bonding jig for manufacturing a ceramic filter according to an embodiment, the body of the jig may be configured by combining two or four bonding guides 100 to surround the edge of the ceramic filter 10, but is not limited thereto.

In manufacturing the ceramic filter 10, a plurality of ceramic honeycomb structures and a bonding agent applied to the bonding surface of the ceramic honeycomb structures are inserted together between the bonding guides 100 separated from each other. After insertion, the ceramic honeycomb structures may be pressurized and bonded with the bonding guides 100 to bond the connection guides which are in contact with each other, thereby manufacturing the ceramic filter 10.

During the bonding process of the ceramic filter 10, the inner surface of the bonding guides 100 and the outer surface of the ceramic filter 10 come into contact with each other, and the inner surface of the bonding guides 100 is connected to the outer surface of the ceramic filter 10. It may be manufactured to have a corresponding shape. Accordingly, since the bonding guide 100 can press the entire region of the ceramic filter 10 evenly, the straightness of the ceramic filter 10 can be improved and the filtration efficiency can be increased.

On the other hand, in the case of large DPFs used in large buses or large vans, in order to prevent damage due to impact, the ceramic honeycomb structures are bonded to be spaced apart at regular intervals to form a shock absorbing layer.

In order to space the ceramic honeycomb structures at regular intervals, a method of injecting spacer materials between ceramic honeycomb structures is generally used. Since the bonding efficiency of the bonding material decreases as the spacer is added, the durability and filtration efficiency of the DPF deteriorate. do. In addition, there is a problem in that the bonding process is complicated and productivity is deteriorated.

In order to solve this problem, the bonding jig for manufacturing a ceramic filter according to an exemplary embodiment includes a bonding guide such that the width of each surface of the ceramic filter 10 including the shock absorbing layer to be formed and the width of the inner surface of the bonding jig corresponding thereto are the same. 100 may be formed.

Accordingly, by manufacturing the ceramic filter 10 by using a bonding jig for manufacturing a ceramic filter, it is possible to form a shock absorbing layer between the ceramic honeycomb structures without using a separate spacer. Therefore, the durability and filtration efficiency of the ceramic filter 10 are improved, the manufacturing process is simplified, and the productivity is improved.

On the other hand, the bonding jig for manufacturing a ceramic filter according to an embodiment is to bond the plurality of ceramic honeycomb structure is inserted into the bonding guide 100 by bonding the bonding guides separated from each other, the bonding guide 100, Means of mutually coupling the

Therefore, the bonding jig for manufacturing a ceramic filter according to an embodiment is provided with a coupling means on a portion of the outer surface of the bonding guide 100 as shown in Figures 1 to 3, mutually contacting the bonding guide 100 Combine. The type of coupling means is not particularly limited, but for example, coupling means having elasticity may be used, such as a tension spring 211, a compression spring 231, and a spring-type cicada ring 221.

First, in the case of using the tension spring 211 as shown in Figure 1 to form a fixing hook 212 is fixed to the tension spring 211 is fixed to a portion of the outer surface of the bonding guides 100 in contact with each other, Both ends of the tension springs 211 may be fixed to the fixing hangers 212, respectively, so that the bonding guides 100 may be coupled to each other. On the other hand, when the bonding guides 100 are in contact with each other when the tensile force is generated in the tension spring 211, the elastic energy of the tension spring 211 is converted into a compressive force or a restoring force to the bonding guide 100 Done.

Therefore, in the bonding process using the bonding jig, the bonding guides 100 are pushed out by the plurality of ceramic honeycomb structures and the bonding agent, and a tensile force is generated in the tension spring 211, and the plurality of bonding guides 100 are used. The ceramic honeycomb structure and the bonding agent are bonded to each other under the compressive force to manufacture the ceramic filter 10.

On the other hand, the bonding agent applied to the bonding surface is a paste-like material having fluidity, the ceramic honeycomb structure has a state of floating on the bonding material, the ceramic honeycomb structure is easily displaced due to the fluidity of the bonding material when an external force is applied. Can be.

However, since the elastic force of the tension spring 211 is proportional to the displacement amount, when the ceramic honeycomb structure is displaced so that a specific portion of the ceramic filter 10 protrudes, the compressive force acts according to the displacement amount. As a result, since displacement is prevented from occurring in a specific portion of the ceramic filter 10, it is possible to manufacture the ceramic filter 10 having high straightness and improved filtration efficiency.

In the case of using the compression spring 231, as shown in FIG. 3, the compression springs 231 are fixed to both end portions of the respective bonding guides 100, thereby joining each other using the compression force of the compression springs. Guides 100 may be coupled to each other. In the case of using the tension spring 211, as shown in FIG. 1, the joint guides 100 which are in contact with each other share one tension spring 211, whereas in the case of using the compression spring 231, FIG. As shown in the figure, one compression spring is separately installed at each end of each bonding guide 100, and the coupling relationship between the two is different from each other. In more detail, as shown in FIG. 3, through holes 232 are formed on both sides of the joining guide 100 and pass through the joining guide 100 to be parallel to the accommodating groove 232. 233 is formed in the bonding guide 100. A bolt member 234 is fitted into the receiving groove 232 and the through hole 233, and one end of the bolt member 234 is fixed to the nut member 235 fixed to the receiving groove 232. At this time, each of the receiving grooves 232, the compression spring 231 is received, the bolt head of the bolt member 234 and the bottom surface of the receiving groove 232, the nut member 235 and the receiving groove 232 It is fitted in the bottom surface of the. Accordingly, when the bonding guides 100 that are in contact with each other are spaced apart, a restoring force is applied to the bonding guides 100 by the compression spring 231, and as a result, a tensile force is applied to the bonding guides 100.

Therefore, as in the case of the tension spring 211, when the bonding guides 100 are pushed by the plurality of ceramic honeycomb structures and the bonding agent, the plurality of ceramic honeycomb structures and the bonding agent are pressed by the bonding guides 100 to be bonded. . In addition, similar to the tension spring 211, the displacement of the ceramic filter 10 by the elastic force of the compression spring 231 is prevented. As a result, it is possible to manufacture a ceramic filter 10 having high straightness and good filtration efficiency.

In addition, in the case of using a cicada spring, as shown in FIG. Can be combined with each other. More specifically, the spring type cicada ring 221 may include a hook, a cicada ring, a return spring, and a fixing part. As shown in FIG. 2, the hook and the cicada ring are formed on the outer surface of the joining guides which are in contact with each other. Each part is fixed by the fixing part. In addition, the return spring is attached to the cicada ring, the compressive force or the restoring force acts between the bonding guides 100 which are in contact with each other by the tensile force of the tension spring 211.

During the joining process, by joining the joining guides 100 that are in contact with each other by hanging the cicada rings, a plurality of ceramic honeycomb structures and the bonding agent in the joining jig are pressed under pressure by receiving a compressive force. In addition, as in the case of the tension spring 211 and the compression spring 231, the bonding material is evenly distributed over the entire area by the elasticity of the return spring, so that the ceramic filter 10 has high straightness and good filtration efficiency. Can be prepared.

On the other hand, in addition to the coupling means having elasticity, for example, by using a tightening means such as bolts and nuts as a coupling means can be manufactured of the bonding jig for manufacturing a ceramic filter.

According to another aspect of the present invention, stepped portions 101 and 102 corresponding to the ends of the other bonding guide 100 in contact with the bonding guide 100 are formed at both ends of the bonding guide 100. For example, assuming that the bonding guide 100 takes a form bent in a '-' shape, stepped portions 101 and 102 are formed at both sides of the bonding guide 100, and the stepped portion 101 of one side is formed. The stepped jaw is formed inward, and the other step 102 is formed with a stepped jaw outward so that the step 101 can be seated.

In another embodiment, as shown in Figure 4 and 5 may further include an elastic means for buffering the ceramic filter 10 on the inner surface of the bonding guide 100.

When the elastic means is attached to the inner surface of the bonding guide as described above, the bonding material is prevented from leaking to the outside of the DPF and the straightness of the DPF is improved, thereby reducing the force that can be applied to the ceramic filter 10 forcibly At the same time protecting the filter 10 and the pressing force is uniformly distributed there is an advantage that the bonding is more stable.

4 is a view showing the configuration of a bonding jig for manufacturing a ceramic filter with a rubber band attached to the inner surface of the coupling member, Figure 5 is a configuration of a bonding jig for manufacturing a ceramic filter with a plate spring attached to the inner surface of the coupling member. One drawing. According to another aspect of the present invention as shown in Figure 4 to 5, the elastic means may be provided with one of the rubber band 311 or the leaf spring (312).

According to the present invention as described above, the DPF is manufactured without using spacers, so that the filtration efficiency and durability are good, and the DPF is manufactured by simultaneously pressing a plurality of ceramic honeycomb assemblies by using a plurality of bonding guides, so that the manufacturing process is simple and productive. This is improved, by attaching an elastic means to the inner surface of the bonding guide, there is an advantage that the bonding material is prevented from flowing out of the DPF and the straightness of the DPF is improved.

Although the present invention has been described with reference to one embodiment shown in the accompanying drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Could be. Accordingly, the true scope of protection of the invention should be defined only by the appended claims.

10: ceramic filter
100: bonding guide
101,102: step
211: tension spring
212 fixing hook
221: cicada spring
231: compression spring
232: receiving home
233: through hole
234: bolt member
235: Nut member
311: rubber band
312: leaf spring

Claims (5)

A plurality of joining guides having a ceramic filter inserted therein and having an inner surface corresponding to an outer surface of the ceramic filter and pressing the ceramic filter; And
Bonding jig for manufacturing a ceramic filter comprising a; coupling means for mutually bonding the bonding guides which are provided on the outer surface of the bonding guides in contact with each other. The method of claim 1,
The coupling means is a joining jig for manufacturing a ceramic filter, characterized in that one of the tension spring, spring-type cicada ring or compression spring. The method of claim 1,
Bonding jig for producing a ceramic filter, characterized in that the stepped corresponding to the end of the other bonding guide in contact with the bonding guide at both ends of the bonding guide. 4. The method according to any one of claims 1 to 3,
Bonding jig for manufacturing a ceramic filter, characterized in that the inner side of the bonding guide is attached to the elastic means for buffering the ceramic filter. The method of claim 4, wherein
Bonding jig for manufacturing a ceramic filter, characterized in that the elastic means is one of a rubber band or a leaf spring.

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